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Toxins 2015, 7, 2494-2513; doi:10.3390/toxins7072494
toxins ISSN 2072-6651
www.mdpi.com/journal/toxins
Article
Three Peptide Modulators of the Human Voltage-Gated Sodium Channel 1.7, an Important Analgesic Target, from the Venom of an Australian Tarantula
Chun Yuen Chow, Ben Cristofori-Armstrong, Eivind A. B. Undheim, Glenn F. King *
and Lachlan D. Rash *
The University of Queensland, Institute for Molecular Bioscience, St Lucia, Queensland 4072,
Australia; E-Mails: [email protected] (C.Y.C.);
[email protected] (B.C.-A.); [email protected] (E.A.B.U.)
* Authors to whom correspondence should be addressed;
E-Mails: [email protected] (G.F.K.); [email protected] (L.D.R.);
Tel.: +61-7-3346-2025 (G.F.K.); +61-7-3346-2985 (L.D.R.);
Fax: +61-7-3346-2101 (G.F.K.); +61-7-3346-2090 (L.D.R.).
Academic Editor: Jean-Marc Sabatier
Received: 15 April 2015 / Accepted: 24 June 2015 / Published: 30 June 2015
Abstract: Voltage-gated sodium (NaV) channels are responsible for propagating action
potentials in excitable cells. NaV1.7 plays a crucial role in the human pain signalling pathway
and it is an important therapeutic target for treatment of chronic pain. Numerous spider
venom peptides have been shown to modulate the activity of NaV channels and these peptides
represent a rich source of research tools and therapeutic lead molecules. The aim of this study
was to determine the diversity of NaV1.7-active peptides in the venom of an Australian
Phlogius sp. tarantula and to characterise their potency and subtype selectivity. We isolated
three novel peptides, μ-TRTX-Phlo1a, -Phlo1b and -Phlo2a, that inhibit human NaV1.7
(hNaV1.7). Phlo1a and Phlo1b are 35-residue peptides that differ by one amino acid and
belong in NaSpTx family 2. The partial sequence of Phlo2a revealed extensive similarity
with ProTx-II from NaSpTx family 3. Phlo1a and Phlo1b inhibit hNaV1.7 with IC50 values
of 459 and 360 nM, respectively, with only minor inhibitory activity on rat NaV1.2 and
hNaV1.5. Although similarly potent at hNaV1.7 (IC50 333 nM), Phlo2a was less selective, as
it also potently inhibited rNaV1.2 and hNaV1.5. All three peptides cause a depolarising shift
in the voltage-dependence of hNaV1.7 activation.
OPEN ACCESS
Toxins 2015, 7 2495
Keywords: Phlogius sp.; spider venom; venom peptide; voltage-gated sodium channel;
NaV1.7; two-electrode voltage clamp electrophysiology; ion channel; mass spectrometry
1. Introduction
NaV channels are responsible for propagating action potentials in excitable cells, most notably nerves
and muscle [1]. As such they are important therapeutic targets for a wide variety of pathophysiological
conditions, including chronic pain, cardiac arrhythmia, and epilepsy [2–4]. Humans and rodents contain
a complex repertoire of nine NaV channel subtypes denoted NaV1.1–NaV1.9. Several studies on the
genetic basis underlying several striking human phenotypes have revealed the importance of human
NaV1.7 (hNaV1.7) as an analgesic target. Gain-of-function mutations in the SNC9A gene that encodes
hNaV1.7 lead to painful inherited neuropathies [5–8], whereas loss-of-function mutations result in a
congenital indifference to all forms of pain [9]. Importantly, therapeutics targeted against NaV1.7 need
to have high selectivity over other NaV channel subtypes such as NaV1.5, which is critical for the cardiac
action potential, and NaV1.6, which is essential for action potential generation at nodes of Ranvier in
myelinated motor neurons [10,11].
NaV channel pharmacology has been largely defined by neurotoxins from natural sources, including
many venom-derived peptides [12,13]. The identification and characterisation of spider-venom peptides
that selectively modulate the activity of NaV channels (so-called NaSpTx peptides) has expanded our
understanding of their mechanisms of action and provided templates for drug development. To date,
twelve families of NaSpTx have been described based on the level of sequence conservation and
disulfide-bond connectivity [14]. Some of these peptides demonstrate excellent affinity and specificity
for particular NaV channel isoforms [15], although none appears to be sufficiently selective for
therapeutic use.
The majority of tarantula-venom peptides are 3.0–4.5 kDa in size and highly disulfide-bridged [16,17].
They typically adopt a highly stable inhibitor cystine knot (ICK) fold that provides resistance to chemical
and thermal degradation as well as proteases, making them promising lead molecules for the
development of ion channel therapeutics [18,19]. Although the increasing use of venom-gland
transcriptomes has led to a rapid increase in the number of available venom-peptide sequences [20], the
venoms of Australian tarantulas remain relatively unstudied. In the present study we report the amino
acid sequence, potency and selectivity of three hNaV1.7-active peptides isolated from the venom of an
unstudied Australian tarantula.
2. Results and Discussion
2.1. Assay-Guided Fractionation and Peptide Purification
Female Phlogius sp. tarantulas from the Cairns region of northern Queensland, Australia were
purchased from a commercial collector. Venom was acquired by electrostimulation of the chelicerae.
Fractionation of crude venom using reversed-phase (RP) HPLC yielded 29 major fractions, indicating
that Phlogius sp. venom is moderately complex (Figure 1A). The majority of components eluted between
Toxins 2015, 7 2496
25% and 40% solvent B (0.043% trifluoroacetic acid in 90% acetonitrile). Electrophysiological
screening of each fraction against hNaV1.7 heterologously expressed in Xenopus oocytes resulted in the
identification of three fractions (18, 19 and 23; highlighted in grey in Figure 1A) that inhibited hNaV1.7.
Three pure peptides were isolated from these fractions using two subsequent steps of RP-HPLC
fractionation on a C18 column. The final step of RP-HPLC fractionation resulted in a single peak for
each active peptide (≥ 95% purity), and a single molecular ion by matrix-assisted laser desorption
ionisation time-of-flight mass spectrometry (MALDI-TOF MS), which did not reveal other contaminants
(Figure 2).
Figure 1. (A) Chromatogram resulting from fractionation of crude Phlogius sp. venom using
C18 RP-HPLC. The numbers correspond to collected fractions, and active fractions are
shaded grey; (B) Representative whole-cell current traces obtained from hNaV1.7 channels
expressed in Xenopus oocytes. Current traces are shown in the absence and presence of F18,
19 and 23, and after ~3 min of peptide washout. Sodium currents were evoked using the
voltage protocol shown above the central trace.
Toxins 2015, 7 2497
10 12 14 16 18 20
0
0.5
1.0
1.5
Time (min)
214 nm
280 nm
10 12 14 16 18 20
0
0.2
0.4
0.6
0.8
12 15 18 21
0
0.1
0.2
Abs
orba
nce
(AU
)
F18 F19
F23
Time (min)
Time (min)
3861
.84
3860 3864 3868 3872
4136 4140 4144 4148
4138
.76
4105
.04
411241084104m/z
m/z
m/z
Abs
orba
nce
(AU
)
Abs
orba
nce
(AU
)
214 nm
280 nm
214 nm
280 nm
Figure 2. Chromatograms resulting from final purification of hNaV1.7-active peptides using
C18 RP-HPLC. Absorbance was monitored at 214 and 280 nm. Inserts show MALDI-TOF
mass spectra, with the monoisotopic M + H+ for each peptide indicated.
2.2. Peptide Sequence Determination
2.2.1. Venom-Gland Transcriptome
A venom-gland transcriptome was obtained using venom-gland mRNA isolated from a single
Phlogius sp. specimen. The transcriptomic data was used solely as a raw database to search for sequence
matches to the proteomic data and it was not annotated.
2.2.2. MALDI-TOF MS Using 1,5-DAN Matrix
The hydrogen-donating ability of 1,5-diaminonapthalene (1,5-DAN) causes partial reduction of
cystines and enhances in-source decay (ISD) fragmentation in the laser plume, providing information on
the number of disulfide bridges and fragments for de novo sequencing [21]. The MALDI-ISD spectra of
peptides from F18, F19 and F23 (Figure 3) revealed a dominant series of c ions. The mass difference
between the fragment ions was used to obtain sequence information for each peptide. An identical
13-residue sequence tag was obtained for F18 and F19, while a distinctly different 10-residue sequence
tag was obtained for F23.
Toxins 2015, 7 2498
Figure 3. Positive-ion MALDI-ISD spectra of (A) F18, (B) F19, and (C) F23, obtained using
1,5-DAN matrix. The deduced peptide sequences are shown above the spectra.
A BLAST search was used to compare the sequence tag “CSKDSDCCAHLEC” obtained from
MALDI-ISD spectra of F18 and F19 against the Phlogius venom-gland transcriptome. This resulted in
matches with 11 mature peptide sequences with lengths varying from 32 to 36 residues (Figure 4), with
the C-terminal region being less conserved than the N-terminal region. These predicted mature peptides
each consist of six cysteine residues, and the intercysteine spacing is consistent with an ICK motif (i.e.,
C–C–CC–C–C) [22]. The observed M + H+ of F18 (4105.04) was 0.77 mass units lower than the
calculated M + H+ (4105.81) of one of the translated cDNA sequences, RL9trimmed_s11674 (see
Supplementary Figure S1 for cDNA and predicted prepropeptide sequences for F18 and F19). This
suggests that F18 corresponds to this sequence but contains an amidated C-terminus, a common
modification in spider-venom peptides that reduces the peptide mass by 1.0 Da. Similarly, the observed
Toxins 2015, 7 2499
M + H+ of F19 (4138.76) was 1.04 mass units lower than one of the transcriptome-derived sequences
(RL9trimmed_rep_c79) which only differs from the sequence identified for F18 by one residue at the
C-terminus. This indicates that the F19 peptide is a paralog of F18 that contains an amidated
phenylalanine at the C-terminus rather than an amidated isoleucine. This difference is consistent with
the mass difference of +33.7 between F18 and F19 and the slightly longer RP-HPLC retention time for
the F19 peptide. This sequence information was sufficient to name the peptides from F18 and F19 as
μ-TRTX-Phlo1a (hereafter Phlo1a) and μ-TRTX-Phlo1b (hereafter Phlo1b), respectively, based on the
rational nomenclature proposed for spider-venom peptides [20]. These 35-residue peptides share a high
level of sequence similarity with tarantula-venom peptides in NaSpTx family 2, as discussed below.
Figure 4. Alignment of mature toxin sequences obtained by BLAST search of the partial
sequences of F18 and F19 obtained from MALDI-TOF MS (highlighted in yellow) against
a Phlogius sp. venom-gland transcriptome. A sequence logo for this alignment is shown,
with conserved Cys residues that form the ICK motif highlighted in red or shaded grey. The
theoretical M + H+ mass is shown for each oxidised peptide (assuming non-amidated
C-termini). The M + H+ values in bold are those for the sequences of F18 and F19.
Surprisingly, the RP-HPLC peak corresponding to F23 in the venom sample used for peptide isolation
(Figure 1A) was absent in venom from the Phlogius specimen used to obtain the venom-gland
transcriptome, even though the chromatograms of the two venoms were otherwise identical (data not
shown). Thus, no additional sequence information was acquired from a BLAST search of the MS-derived
F23 sequence against the venom-gland transcriptome. However, the MS-derived sequence tag obtained
for F23 is similar to other mature toxins belonging to NaSpTx Family 3, as discussed below. Since F23
clearly belongs to a different toxin family than F18 and F19, it was named μ-TRTX-Phlo2a.
2.2.3. MALDI-TOF MS Analysis of Tryptic Peptides
The three Phlogius peptides were reduced and alkylated using the volatile reagents triethyl-phosphine and
iodoethanol, respectively, prior to tryptic digestion. The peptides eluted at a later RP-HPLC retention
time following reduction/alkylation, presumably due to exposure of more hydrophobic side chains (data
not shown). The mass of each peptide was found to increase by 270 Da following reduction/alkylation,
consistent with the presence of six cysteine residues (i.e., the addition of six ethanolyl groups of 45 Da
each) that form three disulfide bonds.
Toxins 2015, 7 2500
To confirm the predicted sequences of Phlo1a and Phlo1b, the reduced/alkylated peptides were
subjected to trypsin digestion and MS/MS sequencing. Peptide mass fingerprints (PMFs) of Phlo1a and
Phlo1b show that four of the six observed digestion fragments for each peptide were identical (1224.82,
1383.77, 2215.32 and 2589.55) (Figure 5A) while the remaining two were 33.9 mass units higher for
Phlo1b than Phlo1a, consistent with an Ile to Phe substitution. All ions observed from the tryptic digest
match the theoretical digest values from the sequences obtained from the venom-gland transcriptome
(Fig 5A,D) with the exceptions of 1548 and 1805 (for Phlo1a and the corresponding ions from Phlo1b),
which are ~0.8 units less than the predicted masses (as determined with a free acid C-terminus),
providing further evidence that the peptides are C-terminally amidated. The sequences of the fragments
corresponding residues 4–22 and 23–35 were determined by MS/MS (Figure 5B,C) and they match the
predicted sequences. Taken together, these results support the sequences of Phlo1a and Phlo1b predicted
from the transcriptomic data (Figure 4).
Figure 5. (A) MALDI-TOF mass spectra of tryptic digests of Phlo1a (upper panel) and
Phlo1b (bottom panel). Amino acid positions (and number of missed cleavages) are indicated
above the peak masses; (B) MS/MS analysis of the Phlo1a precursor ions 1805.20 and (C)
2215.32; (D) Comparison of the observed and theoretical M + H+ for the ions observed, their
corresponding residue positions and fragment sequence.
Toxins 2015, 7 2501
Phlo2a belongs to NaSpTx3, which is comprised entirely of short (29–33 residue) tarantula ICK
peptides [14,16]. NaSpTx3 is characterised by 26 highly conserved N-terminal residues
[YCQKWMWTCDxxRKCCE(G/D)(L/M)VCRLWC(K/R)] and a more variable C-terminal region
often containing one or more of Lys, Arg, Ile or Leu. Based on this high level of sequence identity
and the sequence tag obtained from 1,5 DAN MS showing that positions 11 and 12 are Glu,
and position 18 is Asp, we predicted that Phlo2a has an N-terminal sequence of
YCQKWMWTCDEERKCCED(L/M)VCRLWC(K/R) and compared our experimental data to this
prediction. Tryptic digestion and MS analysis of Phlo2a (with ethanoylated Cys residues) revealed a
fragment fingerprint that was somewhat consistent with this prediction (Figure 6A). MS/MS analysis of
several fragment ions revealed that positions 8, 19 and 26 are Leu, Met and Lys, respectively (Figure
6B,C). The main exception to our prediction was the N-terminal four residues, which with a Tyr was
predicted to have an m/z of 570.22; however, this ion was not present. N-terminal sequencing of another
NaSpTx3 family member by Edman degradation showed that the N-terminal Tyr can be substituted by
a Ser (L.D. Rash, unpublished observation). Using an N-terminal Ser residue and the corrected residues
at 8, 19 and 26, we obtain complete agreement between the ions observed in the
1,5-DAN mass spectra, the trypsin digest, and MS/MS fragments and the theoretical values for these
ions for the first 26 residues of Phlo2a (Figure 6C).
Figure 6. (A) MALDI-TOF MS analysis of peptides fragments from tryptic digest of Phlo2a.
Amino acid positions and the number of missed cleavage are indicated above the peak
masses. (B) MS/MS analysis of tryptic peptides with m/z 1311.72. (C) Comparison of
observed and theoretical M + H+ for tryptic fragments of alkylated Phlo2a obtained using
MALDI-TOF MS.
Toxins 2015, 7 2502
2.2.4. Ladder Sequencing Using Carboxypeptidase Y
MS analysis of peptides resulting from tryptic digest of Phlo1a and Phlo1b confirmed almost the
entire mature toxin sequence predicted from the venom-gland transcriptome, and suggest that the
C-terminal residue is amidated. In order to confirm the nature of the C-termini, the reduced/alkylated
peptides were digested with carboxypeptidase Y (CPY), an exopeptidase that cleaves one residue at a
time from the C-terminus. MALDI TOF MS analysis of the CPY digestion of Phlo1a and Phlo1b taken
over a period of 60 min provided experimental evidence for the sequence of the nine last amino acid
residues and confirmed that the C-terminal residues are indeed amidated (Figure 7). In the case of
Phlo1a, the observed C-terminal residue mass was 112.07, exactly 1 unit less than the theoretical residue
mass of isoleucine or the isobaric leucine with a carboxylic acid. However, a search against the
venom-gland transcriptome only revealed a match with a C-terminal isoleucine, and hence we concluded
that this must be the C-terminal residue in Phlo1a. Likewise, CPY digestion clearly revealed that the
C-terminal residue of Phlo1b is phenylalanine-amide (146.12 as opposed to the free acid residue mass
of 147.07).
Figure 7. MALDI-TOF mass spectra obtained at different times points (from 1 to 60 min)
during CPY digestion of reduced/alkylated (A) Phlo1a and (B) Phlo1b.
Approximately 12% of spider toxins are C-terminally amidated [23]. In addition to a possible role in
peptide stability, C-terminal amidation can modulate biological activity. The 35-residue spider-venom
peptide huwentoxin-IV (HwTx-IV) is a member of NaSpTx Family 1 isolated from venom of the
tarantula Haplopelma schmidti (formerly known as Ornithoctonus huwena) [24]. Remarkably, native
HwTx-IV with C-terminal amidation inhibits hNaV1.7 with is ~50-fold higher potency than a
recombinant version with a C-terminal carboxylate group. Although not in the same peptide family as
HwTx-IV (NaSpTx Family 1), amidation might have substantial effects on the potency and selectivity
Toxins 2015, 7 2503
of Phlo1a and Phlo1b and this should be examined in future studies. The experimental evidence for the
complete sequences of Phlo1a and Phlo1b and the N-terminal sequence of Phlo2a is summarised in
Figure 8. The verified sequences confirm our classification of Phlo1a and Phlo1b into NaSpTx2. Family
2 peptides range in length from 33 to 41 residues with three disulfide bonds and they constitute the
largest family of spider toxins that inhibit NaV channels (Figure 8B) [14]. The most similar toxin to
Phlo1a/1b with 91% identity is μ-theraphotoxin-Cj1a (91%), a NaV channel modulator from venom of
the tarantula Chilobrachys guangxiensis [25]. Additionally, Phlo1a shares 51% sequence identity with
β/ω-TRTX-Tp1a (ProTx-1) from venom of the tarantula Thrixopelma pruriens, a potent blocker of
human NaV1.5, NaV1.7 and NaV1.8 channels [26].
Figure 8. (A) Summary of the experimental evidence for amino acid sequences of Phlo1a
and Phlo1b, and partial sequence of Phlo2a, in comparison to predictions from the
venom-gland transcriptome (confirmed sequence in bold); (B) Sequence alignment of Phlo1a
and Phlo1b with other members of the NaSpTx2; (C) Sequence alignment of Phlo2a with other
members of the NaSpTx3. Cysteine residues are shaded.
2.3. Electrophysiological Characterisation of Phlogius Peptides
2.3.1. Effects of Phlo1a, Phlo1b and Phlo2a on hNaV1.7 Currents
We investigated the ability of Phlo1a, Phlo1b and Phlo2a to inhibit currents carried by hNaV1.7
channels heterologously expressed in Xenopus oocytes using two-electrode voltage-clamp (TEVC)
Toxins 2015, 7 2504
electrophysiology. The three peptides inhibited hNaV1.7 in a concentration-dependent manner (Figure 9).
Phlo1a and Phlo1b, which are identical except for their C-terminal residue, inhibited hNaV1.7 with
similar potency (IC50 values of 459 and 360 nM, respectively) (Figure 9C), indicating that the
C-terminal residue is not critical for interaction with hNaV1.7. Phlo2a, which belongs to NaSpTx Family
3, inhibited hNaV1.7 with an IC50 of 333 nM, making all three peptides similarly potent on hNaV1.7
(Figure 9). After application of 1 μM Phlo2a, the current level had not plateaued after 20 min. Notably,
the concentration-effect curve for Phlo2a inhibition of hNaV1.7 currents was steeper compared with that
of Phlo1a and Phlo1b, suggesting that it may bind to the channel at multiple sites with positive
cooperativity. Several spider toxins have been shown to bind multiple sites on vertebrate NaV channels; for
example, ProTx-II binds to the voltage sensors in domains I, II and IV of rat NaV1.2 [27].
A
B
1 µA
10 ms
1 µA
10 ms
NaV1.7 Na
V1.7
1 µM
0.1 µM
control
Phlo1a
1 µM
0.1 µM
control
Phlo1b2
control
0.1 µM
1 µM
2 µA
10 ms
-2
-1
0
0 10 20 30
Pea
k cu
rren
t (µA
)
Time (min)0 10 20 30
-5
-4
-3
-2
-1
0
Pea
k cu
rren
t (µA
)
Time (min)0 10 20 30 40
-8
-6
-4
-2
0P
eak
curr
ent (
µA)
Time (min)
10 nM
0.1 µM
1 µM
wash
10 nM
0.1 µM
1 µMwash
10 nM
0.1 µM
1 µMwash
Phlo1atime control
Phlo1btime control
Phlo2atime control
Phlo2a
NaV1.7
-9 -8 -7 -6 -50.0
0.5
1.0
Log [peptide] (M)
Nor
mal
ised
cur
rent
Phlo1a: IC50 = 459 ± 46 nM (0.87)
Phlo1b: IC50 = 360 ± 39 nM (1.04)
Phlo2a: IC50 = 333 ± 19 nM (2.26)
C
Figure 9. Effects of Phlogius peptides on hNaV1.7 expressed in oocytes. (A) Whole-cell
current traces in absence (control) and presence of 0.1 or 1 μM peptide. Currents were
evoked by a 50-ms step depolarisation to 0 mV from a holding potential of −80 mV every
10 s. (B) Time course for inhibition of hNaV1.7 by different peptide concentrations. Time
controls show stable current amplitude in the absence of peptide. (C) Concentration-effect
curves for inhibition of hNaV1.7 by Phlo1a, Phlo1b and Phlo2a (n = 5–7). Data are
mean ± S.E.M. Hill coefficients are shown in parentheses.
Toxins 2015, 7 2505
2.3.2. Effect of Phlo1a, Phlo1b and Phlo2a on the Current-Voltage Relationship for hNaV1.7
Many spider-venom peptides, such as the ceratotoxins (CcoTx1, CcoTx2, CcoTx3), phrixotoxin
(PaurTx3), and ProTx-I, inhibit NaV channels by shifting the threshold for channel activation to more
positive potentials [26,28,29]. Thus, we investigated the effects of Phlogius peptides on the current-voltage
(I-V) relationship for hNaV1.7 using step-depolarisations ranging from −60 to +70 mV from a holding
potential of −80 mV. Figure 10 shows that, under control conditions, the threshold of initial channel
activation was approximately −30 mV, the V0.5 was about −18 mV, and the peak current was evoked
between −10 and −5 mV. All three peptides shifted the V0.5 for activation of hNaV1.7 to more positive
potentials in a concentration-dependent manner; the shift was ~4 mV at 300 nM and 10–12 mV at
1 μM peptide (Figure 10A–C, summarised in Figure 10D). Furthermore, the inhibition of hNaV1.7 by
all three peptides was voltage-dependent, with lower inhibition at more positive test pulses (insets to
Figure 10A–C). Given that Phlo1a, Phlo1b and Phlo2a all cause concentration-dependent, depolarising
shifts in the I-V relationship for hNaV1.7, we propose that they are gating modifiers that inhibit channel
activation via interaction with one or more voltage-sensor domains [15,27,30].
-60 -50 -40 -30 -20 -10 10 20 30 40 50 60 70
-1.0
-0.5
0
Membrane potential (mV)
-1.0
-0.5
-60 -50 -40 -30 -20 -10 10 20 30 40 50 60 700
Membrane potential (mV)
NaV1.7
control
300 nM Phlo1a
1 μM Phlo1a
control
300 nM Phlo1b
1 μM Phlo1b
A B
-1.0
-0.5
-60 -50 -40 -30 -20 -10 10 20 30 40 50 60 700
Membrane potential (mV)
control
300 nM Phlo2a
1 μM Phlo2a
C D
Control 300 nM 1 μMPeptide
Phlo1a
Phlo1b
Phlo2a
–18.6 –15.3 –8.6
–17.7 –13.1 –7.5
–19.3 –15.1 –6.5
-30 -20 -10 0 10 20 30
0.0
0.5
1.0
Memb pot (mV)
(Io -
I)/ Io
-30 -20 -10 0 10 20 30
0.0
0.5
1.0
Memb pot (mV)
(Io -
I)/ Io
-30 -20 -10 0 10 20 30
0.0
0.5
1.0
Memb pot (mV)
(Io -
I)/ Io
I / Io
I / Io
I / Io
Figure 10. Effect of Phlo1a (A), Phlo1b (B) and Phlo2a (C) on the I-V relationship for
hNaV1.7. Oocytes were held at −80 mV, and sodium currents were elicited using 50-ms
depolarising steps from −60 to +70 mV in 10 mV increments. I-V relationships were
obtained in the absence (control, ) and presence of each peptide at 300 nM () and 1 μM
(). All currents were normalised to the maximum control peak current for each oocyte.
Data are mean ± S.E.M. (n = 6). Insets in panels A–C show the voltage-dependence of
inhibition. (D) Quantitation of the effect of each peptide on the V0.5 (in mV) of hNaV1.7.
Toxins 2015, 7 2506
2.3.3. Subtype Selectivity of Phlogius Toxins
In order to gain insight into the NaV subtype selectivity of the Phlogius peptides, we also examined
their effect on rNaV1.2 and hNaV1.5. NaV1.2 is a TTX-sensitive channel that is predominantly expressed
in the central nervous system while NaV1.5 is a cardiac-specific isoform. Phlo1a inhibited rNaV1.2 and
hNaV1.5 much less potently than hNaV1.7 resulting in less than 20% inhibition at 1 μM (Figure 11A,B).
At a concentration of 1 μM, Phlo1b had a similar effect as Phlo1a at hNaV1.5 but it was slightly more
potent at rNaV1.2, with 1 μM peptide causing a 37% reduction in currents (Figure 11A,B). This indicates
that the single C-terminal residue difference between these peptides (Ile to Phe) influences their Nav
subtype selectivity. Variations in NaV subtype selectivity due to small sequence variations have been
noted previously in spider-venom peptides. Two tarantula toxins isolated from Ceratogyrus cornuatus
(CcoTx1 and CcoTx2) differ by only one residue, but display dramatic differences in their inhibitory
effect on NaV1.3 [28]. CcoTx1 does not inhibit NaV1.3, whereas CcoTx2 reduces NaV1.3 currents with
an IC50 of 88 nM [28].
A
2 µA
10 ms
NaV1.2
1 µM Phlo1a control
1 µA
10 ms
1 µM Phlo1b control
B1 µM Phlo1b control
1 µM Phlo1a control
NaV1.5
NaV1.2: IC
50= 404 ± 64 nM (1.74)
NaV1.5: IC
50= 218 ± 50 nM (1.76)
Nor
mal
ised
cur
rent
0.0
0.5
1.0
-9 -8 -7 -6Log [Phlo2a] (M)
10 ms
2 µA
NaV1.2
1 µM Phlo2a
control
1 µA
10 ms
NaV1.5
C D
1 µM Phlo2a
control
Figure 11. Effects of Phlo1a and Phlo1b on (A) rNaV1.2 and (B) hNaV1.5 expressed in
Xenopus oocytes. Currents were evoked by a 50-ms step depolarisation to 0 mV from a
holding potential of −80 mV every 10 s. (C) Effect of Phlo2a on rNaV1.2 and hNaV1.5
currents in Xenopus oocytes. (D) Concentration-effect curves for inhibition of rNaV1.2 and
hNaV1.5 currents by Phlo2a (n = 5). Data are presented as mean ± S.E.M and the Hill
coefficients are shown in parentheses.
In contrast to Phlo1a and Phlo1b, Phlo2a strongly inhibited rNaV1.2 and hNaV1.5 at a concentration
of 1 μM (Figure 11C). The concentration-effect curves obtained for inhibition of rNaV1.2 and hNaV1.5
by Phlo2a yielded IC50 values of 404 ± 64 nM and 218 ± 50 nM, respectively (Figure 11D). These values
are very similar to the IC50 of 333 nM obtained for inhibition of hNaV1.7 by Phlo2a, indicating that this
Toxins 2015, 7 2507
peptide has a low degree of NaV subtype selectivity, which is common for peptides from this toxin
family. The most potent blocker of hNaV1.7 within this family is β/ω-TRTX-Tp2a (ProTx-II), which
inhibits this channel with an IC50 of 0.3 nM [31]. However, like Phlo2a, ProTx-II also lacks subtype
selectivity and potently inhibits NaV1.2 and NaV1.5 (IC50 = 41 and 79 nM, respectively) [31]. ProTx-II
shifts the voltage-dependence of activation of NaV1.5 to more positive potentials and has a similar
potency to ProTx-I [26]. An extensive mutagenesis study of NaV.1.5 led to the conclusion that ProTx-II
does not bind to receptor site 4 on the domain II voltage sensor [32], suggesting the existence of a novel
toxin-binding site. In contrast, a later study concluded that ProTx-II is gating modifier that reduces
sodium conductance by trapping the domain II voltage sensor in the closed state [33]. Consistent with
this study, elegant work with chimeric KV1.2/NaV1.2 chimeric channels indicated that ProTx-II has
complex pharmacology and is capable of binding to the voltage sensors in domains I, II
(receptor site 4), and IV (receptor site 3) of NaV1.2 [27].
Due to the small amounts of native Phlo1a and Phlo1b that were available and their relatively weak
activity at rNaV1.2 and hNaV1.5, we could not obtain complete concentration-effect curves, and
consequently the IC50 values for these channels remain to be determined. Nevertheless, it is clear that
both peptides inhibit hNaV1.7 more potently than rNaV1.2 and hNaV1.5, making them a more promising
starting point for development of hNaV1.7-selective analgesics than Phlo2a.
We have shown that venom from Australia theraphosid spiders represents an untapped source of
potential hNaV1.7 inhibitors. Electrophysiology-guided fractionation of venom from a Phlogius sp.
tarantula led to the isolation of three disulfide-rich peptides that inhibit hNaV1.7 with similar IC50 values
in the range 330–470 nM. All three peptides act as gating modifiers that shift the voltage-dependence of
channel activation to more depolarised potentials. As for other members of NaSpTx2 and NaSpTx3, we
propose that this occurs by virtue of their binding to one or more of the voltage sensor domains [14,15,27].
One of these peptides (Phlo1a) has a high level of selectivity for NaV1.7 over NaV1.2 and NaV1.5 and
thus it represents a good starting point for the rational engineering of subtype-selective inhibitors of
NaV1.7 for development as analgesics.
Future studies of these peptides will focus on elucidation of structure-function relationships and
identification of their binding site on hNaV1.7 with a view to rational engineering of more potent and
subtype-selective analogues. Overall, the discovery of new NaV channel modulators and the further
characterisation of known NaV modulators will extend our understanding of NaV channel function and
facilitate the development of new therapeutic treatments.
3. Experimental Section
3.1. Venom Fractionation and Peptide Purification
Crude venom obtained by electrostimulation was diluted ~100-fold into 10% solvent B (0.043%
trifluoroacetic acid (TFA, Auspep, Tullamarine VIC, Australia) in 90% acetonitrile (ACN)), centrifuged
(17,000 g, 15 min, 4 °C) and fractioned via RP-HPLC using a Prominence HPLC system (Shimadzu,
Kyoto, Japan). Venom (2.5 mg) was loaded onto a to an Agilent C18 column (250 × 9.4 mm, 300 Å) and
fractionated using the following gradient: 15% solvent B in solvent A (0.05% TFA in water) at a flow
rate of 3 mL/min for 2.5 min, followed by a linear gradient of 15%–45% solvent B over 52.5 min, then
Toxins 2015, 7 2508
45%–70% solvent B over 5 min. Absorbance was monitored at 214 nm and 280 nm using a Shimadzu
SPD-10AVP UV-VIS detector. Fractions were collected manually and dried on a vacuum rotary
evaporator. The dried fractions were dissolved in water and aliquots of each fraction were assayed for
activity against hNaV1.7 expressed in Xenopus oocytes (see below for details). Active fractions were
further separated using a Thermo C18 column (150 × 4.6 mm, 5 μm) and a gradient of 20%–50% solvent B
over 60 min at a flow rate of 1 mL/min. Peptide purity was verified by RP-HPLC using a Thermo C18
column (50 × 2.1 mm, 5μm) with a gradient of 10%–50% solvent B for 16.5 min at a flow rate of 0.25
mL/min. Unless otherwise stated, all reagents were purchased from Sigma, St Louis, MO, USA.
3.2. MALDI-TOF Mass Spectrometry
Peptide masses were verified by MALDI-TOF MS using a model 4700 Proteomics Bioanalyser
(Applied Biosciences, Foster City, CA, USA). α-Cyano-4-hyroxy-cinnamic acid (CHCA) was used as
the matrix. RP-HPLC fractions were mixed 1:1 (v/v) with CHCA (7.5 mg/mL in 50/50 ACN/H2O, 0.1%
TFA). MALDI–TOF mass spectra were collected in reflector positive mode and the reported masses are
monoisotopic M + H+ ions. For sequencing of intact peptides, 1,5-DAN was used as a reductive
matrix [34]. The active fractions were mixed 1:1 (v/v) with 1,5-DAN (15 mg/mL in 50/50 ACN/H2O,
0.1% formic acid (FA)).
3.3. Reduction/Alkylation of Cysteine Residues
Purified peptides were reduced and alkylated using triethylphosphine and iodoethanol respectively,
as previously described [35]. Approximately 3 μg of each pure active peptide was dissolved in 50 μL of
100 mM ammonium carbonate. The reduction/alkylation reagent was prepared by mixing 97.5% ACN,
2% iodoethanol and 0.5% triethylphosphine (v/v). An equal volume of the reagent was added to the
peptide sample and then the reaction mixture was incubated for 2 h at 37 °C. At the end of the incubation
period, samples were vacuum-dried on a speedvac for at least 1 h. The dried samples were re-suspended
in 0.1% TFA and desalted using RP-HPLC with a Thermo C18 column (15%–50% solvent B over
30 min at a flow rate of 1 mL/min). The masses of the reduced/alkylated peptides were determined by
MALDI-TOF MS prior to trypsin digestion.
3.4. Tryptic Digestion
The reduced and alkylated peptides were digested using a 20:1 (w/w) ratio of peptide to trypsin
(Proteomics Grade, Sigma) in 30 mM ammonium bicarbonate, pH 8. The samples were incubated for
2 h at 37 °C. Digestion was quenched by the addition of 1% FA and the resultant cleavage products were
analysed using MALDI-TOF MS. MS ions were selected for tandem mass spectrometry (MS/MS)
followed by manual analysis of spectra and comparison to theoretical fragmentation using
ProteinProspector Tools [36].
3.5. Carboxypeptidase Y Digestion
Reduced and alkylated peptides were dissolved in 15 μL of 100 mM ammonium acetate buffer, pH
5.5. CPY (1 μL of 2 ng/μL; Sequencing Grade, Sigma) was added to the peptide solution. The mixture
Toxins 2015, 7 2509
was left to react at 37 °C and aliquots were taken at 1, 2, 5, 10, 15, 30 and 60 min for MS analysis. The
digestion was stopped at the desired time by the addition of 2 μL of 1% FA. MS analysis of the digestion
products was performed by mixing 0.5 μL of the digest with 0.5 μL of CHCA matrix. Each dried spot
was washed on-plate by adding 0.5 μL of 1% FA, allowing it to permeate the matrix for ~30 s, then excess
liquid was removed with a Kimwipe via capillary action.
3.6. Preparation and Analysis of Venom-Gland Transcriptome
The venom gland of a single specimen of Pholius sp. was dissected four days after depleting the gland
of venom by electrostimulation. RNA was extracted using a standard TRIzol (Life Technologies,
Carlsbad, CA, USA) protocol, and enriched for poly(A) RNA using an Oligotex mRNA kit (Qiagen,
Venlo, Limburg, Netherlands). The resulting mRNA was submitted to the Australian Genome Research
Facility (Brisbane, QLD, Australia) where it was reverse transcribed, fragmented, and ligated into a
10-base multiplex identification tag before it was sequenced on a Roche 454 GS FLX+ platform. After
removal of low-quality reads, the remaining 72,023 reads were assembled de novo using MIRA v3.2.1
(2011) (Open source via http://sourceforge.net/projects/mira-assembler/files/MIRA/Older releases/),
resulting in a total of 10,621 contigs (average length 523 bases) and 2904 singlets (average length 335
bases). Open reading frames were predicted, translated and compiled into a local search database using
CLC Main Workbench 7 software (CLC bio, Aarhus, Denmark, 2014).
Sequence tags obtained from MALDI-TOF MS analysis were BLAST searched against the Phlogius
sp. venom-gland transcriptome using CLC Main Workbench 7 software (CLC bio, Aarhus, Denmark,
2014). Peptide sequences were compared with related spider toxins in the ArachnoServer database
(www.arachnoserver.org) using the BLAST search form [23]. Multiple sequence alignments were
performed using the program ClustalW then manually refined.
3.7. Heterologous Expression of Vertebrate NaV Channels in Frog Oocytes
Plasmids containing cloned rNaV1.2, hNaV1.5 and hNaV1.7 were linearised, then capped cRNAs were
synthesised using a T7 mMESSAGE-mMACHINE transcription kit (Ambion, Austin, TX, USA). Stage
V-VI oocytes were obtained from anesthetised Xenopus frogs and prepared as previously described [37].
Oocytes were injected with 20–40 ng of cRNA (Nanoject 2000; WPI, Sarasota, FL, USA) and incubated
for 2–6 days at 17 °C in ND96 solution (96 mM NaCl, 2 mM KCl, 1 mM CaCl2, 2 mM MgCl2, 5 mM
HEPES, pH 7.4), supplemented with 2.5 mM sodium pyruvate, 50 μg/mL gentamicin and 2.5% horse
serum prior to electrophysiological recordings. All work with animals was carried out in strict
accordance with the recommendations in the Australian code of practice for the care and use of animals
for scientific purposes. The protocol was approved by the Anatomical Biosciences group of the Animal
Ethics Committee at The University of Queensland (Approval Number QBI/059/13/ARC/NHMRC).
3.8. Two-Electrode Voltage-Clamp Electrophysiology
Two-electrode voltage clamp (TEVC) recordings were performed at room temperature (20 °C–22 °C)
under voltage-clamp (Axoclamp 900A, Molecular Devices, Sunnyvale, CA, USA) using two standard
glass microelectrodes of 0.5–1 MΩ resistance when filled with 3 M KCl solution. Stimulation, data
Toxins 2015, 7 2510
acquisition, and analysis were performed using pCLAMP software (Version 10, Molecular Devices,
Sunnyvale, CA, USA). Peptide stock solutions were made up to 30 μM, and serial dilutions were
prepared in ND96 solution (pH 7.4) containing 0.1% bovine serum albumin (BSA). Venom peptides
were applied directly to the recording chamber to prevent adsorption to plastics.
NaV channel recordings were performed on oocytes clamped at −80 mV. Data were sampled at
20 kHz and filtered at 2 kHz. Inward sodium currents were elicited by a 50-ms depolarising step to
0 mV every 10 s. Once the peak current had stabilised (typically ~3 min), serial dilutions of peptides
were applied to oocytes to obtain concentration-effect curves. Data were analysed using Clampfit 10.2
and Prism 6.0 (GrahPad Software, La Jolla, CA, USA, 2013). The Hill equation was fit to the data to
obtain the half-maximal inhibitory concentration (IC50) values and Hill coefficient (nH). Data are
presented as mean ± S.E.M. (n = number of oocytes). I-V relationships in the absence and presence of
300 nM and 1 μM peptide were obtained on oocytes clamped at −80 mV; families of currents were
evoked by applying 50-ms depolarising steps from −60 mV to +70 mV with 10-mV increments every
10 s. After acquiring the control I–V curve, the first concentration of peptide was added and the
inhibitory effect was allowed to plateau (a test pulse from −80 to 0 mV every 10 s) before obtaining an
I–V curve in the presence of peptide. This was repeated for the second concentration of peptide. Data
were normalised to the maximal peak current and analysed using Clampfit 10.2 and Prism 6.0.
3.9. Deposition of Protein and cDNA Sequence Information
All protein and cDNA sequence information derived for Phlo1a, Phlo1b, and Phlo2a has been
submitted to the publicly accessible ArachnoServer spider-toxin database [23,38]. The ArachnoServer
accession numbers for Phlo1a, Phlo1b, and Phlo2a are AS002321, AS002322, and AS002323,
respectively. Toxin records can be accessed directly using the final four digits of the accession number;
for example, for Phlo1a, navigate to www.arachnoserver.org/toxincard.html?id=2321.
Supplementary Materials
Supplementary materials can be accessed at: http://www.mdpi.com/2072-6651/7/7/2494/s1.
Acknowledgments
We thank Prof. Richard Lewis for the rNaV1.2 and hNaV1.5 clones and Dr Frank Bosmans for the
hNaV1.7 clone. We acknowledge financial support from the Australian Research Council (Discovery
Grant DP110103129 to G.F.K.)
Author Contributions
L.D.R. and G.F.K. designed the study. C.Y.C., B.C.-A. and E.A.B.U. performed the experiments.
C.Y.C., B.C.-A., E.A.B.U., L.D.R. and G.F.K. analysed the data. All authors contributed to writing
the manuscript.
Conflicts of Interest
The authors declare no conflict of interest.
Toxins 2015, 7 2511
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